![]() Regardless of whether you’re working with raster vs vector data, Land id™ (formerly MapRight) has all of the tools you need for success. Plus, if you have multiple data fields and attributes to store, vector models will once again be the better choice, as vector data points can have as many attributes as you choose. In contrast, vector points, lines, and polygons can be scaled up or down without sacrificing quality. To start, the graphical output tends to be much more aesthetically pleasing, especially considering that raster models can end up looking rather pixelated when scaled. When it comes to displaying linear paths and feature boundaries, vector models are by far the better choice. Plus, while vector models tend to do a poor job storing and displaying continuous data, the grid surface of a raster model is well suited for doing so. Since each raster cell represents just one value or attribute, it’s much easier (and faster) to do mathematical calculations and modeling with raster data. For instance, temperature, soil pH, elevation, CO2 levels, and air pressure would all be continuous data types. Instead, it smoothly transitions from one value to the next. Continuous data is often a measure of concentration level, and there aren’t sharp changes between values. Continuous data, on the other hand, is more fluid. Examples of discrete objects would be a pond, building, or county. There are definite changes in characteristics between them, and they have exact boundaries. ![]() In general, discrete data is best handled by vector models, while continuous data is best left to raster models.ĭiscrete features are typically nouns. When deciding between raster vs vector models, one of the primary things to consider is whether the data you are representing is continuous or discrete. Which Should You Use? Continuous vs Discrete Data This could be a city, a lake, a building structure, or virtually anything that takes up space. And finally, vector polygons are used to represent the boundaries and area of a feature. Unlike points, vector lines are used to represent linear features such as roads, streams, and trails, and since they have a start and an endpoint, you can measure their length. So, you’ll often see cities, buildings, or trees represented as points. Points are typically just latitude and longitude, and they are often used to represent abstract features, features that are too small to display as a line or polygon on the map, or sample locations. Vector points are one XY coordinate they have no length or width, therefore no area. based on its discrete boundaries.Īnother difference between raster vs vector data is that vector data comes in three types: points, lines, and polygons. These coordinates, also known as vertices, define the shape of an object such as a river, building, forest, road, etc. While raster data is composed of cells in a matrix, vector data is composed of XY coordinates. ![]() One of the main differences between raster vs vector data is how it is represented. ![]() In an image, each pixel will have a red, green, and blue value, but the value of a pixel could also represent average rainfall, temperature, elevation, CO2 levels, etc.Įvery pixel in a raster dataset is identical in size and shape, and the amount of land each pixel represents is known as the spatial resolution. Each pixel in this grid, also referred to as a cell, contains a value of some sort, which represents a piece of data. Raster data is represented as a matrix of pixels arranged into rows and columns, aka, a grid. So, what is raster vs vector data, and which is best? Below, we’ll dive into everything you need to know about these two data representations. While attribute data is always represented in tabular format, geospatial data is a bit more varied, as it can be represented in either vector or raster forms. What makes GIS so interesting is that it can handle both attribute data, which describes the characteristics of a feature, and geospatial data, which describes the absolute and relative location of a feature. However, a lot of programs deal with data. ![]() Without data, there would be no reason for GIS to exist the whole point of GIS is to create, manage, analyze, and map data. ![]()
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